Ejector-condenser



June 19, 11945.

H. L. MURRAY EJEcToR coNDENsER Filed Nov. 22, 1941 2 Sheets-Sheet 1 June 19, 1945 "H.' MURRAY 2,378,425

EJECTOR CONDENSER Filed Nov. 22, 1941 l. 2 sheets-.sheet 2 Inpemf o HENRY LAMaA/r lvl/B647 UNITED STA-TES Patented June 19, 1945 PATENT OFFICE l *d "'EJEoToR-ooNDENsER l i* HenryLamontMurray,Epsom, Auckland,

. New Zealand Application: Novemberv 22, 1941,semaine; k420,122 YalniNewzealand,.Australia,iand-Great Britain kFebruary 22,;1938

d d Y d d A12pm-uns. 01. J'caos-,103) This appli-cation is a, :eentinuauensin-part Vor lpressures and more -particularlyflto condensing Aand/orexhausting4 means -Whichemploythe Wellknown liquid' jet principle, of operationlfffThe y condensing "and/or exhausting means,- )the subject Ymatter of -the present'finventio'n Will'lherenafter, furthe Ysake of 1brevity,-be referredftoas a manifold'condenseri Thef-useof bothsurfa'ce and ijetcondensershas v f long'been known, wherein ythe degree A' 'o1'^vacuum generatedjis common Vthroughout 'the Londenser unit. Suchrelnement has 'been reachedjinlthe design of those condensers that higheiciencies inthe condensers themselves are obtained: -I-Iowever', Where the Aseveral parts of anassernbly Are` quire different degrees :of vacuum, 1ite-has lhitherto been necessary,fin the Aabsence of complicated lintermediary equipment, to employ av separate single-stage condenser toggenerateieachf differ- 4 ent degree'ofwacuum'required. u f

Obviously'where morethan pnejdegree'of'vac# vuumjis'` demanded, this requirement increases apprefpz'iablyv the .rst cost of `the installation, airincrease which mayjbe o'f such importance .asto result indrasticcurtailment of the'utilisatonof theequipment. "Forexample, in'mysaid'coapend- -ing application out of which this application 4-is assembly.l Followingthexproducticn of ymynev` invention according tov this application',` however,

I Wasenabledto 11e-design the assemblyftqemploy only one condenser toV vproduce 'simultaneously the required different degreesofivacuum for vthe several elementsvof the assembly. AsV a'rresult thereof, .I have achieved appreciablel saving lboth in ',rst cost and'finjoperatmg'and maintenance costs. v 1t `vvas to avoid ythe' increased 'costfoijand jcomf plication attendantfup'on I"theus'e'of' a 'separate condenseriwith 'eachvacuum stagecffcomplicated assemblies, asvrellas jtd-inset the exigencies fof modern-'day highepressure competitionI iin the varied fields of .industrial equipment,v that I'y gave 4careful;st1.idy=:1eading ,towardsthe evolution of mynewrmanifold zcondenser. Its production has made :possible the simplied design of many Idi d versied types of industrial Vacuum equipment,

and has 'so reduced the costs thereofithat-:thefacceptance of `:such equipment vin the. arts and fin-- dustries has-beenimuch more widespread'thanfhas hitherto been the case. My new :manifold lcondenser ;can readilyube :designed to. `provide within wide limits, any 4required. :degrees Yof vacuum; and

these desired'-.degrees,.of ivacuumgcan lbe :obtained with comparativelyy slight structural vvariation tof the condenser, and with nofchange in its fundamentaldesign.

Accordingly my new manifold condenserpmay be vsaid to embody,.;inter a1ia,..the :following rvadvantagesandffeatures: y '-LThe ,f'ability under load'V to simultaneously produce and maintain diverse degrees Lof sub-'atmospheric pressure in` isolated 'zones vvithinthe one apparatus.

l 2; The provision Vwithin the one :apparatus .of

separate zonesv fior simultaneously 1 generating fdiverse degrees 'of ysub-atmospheric pressure, `.each zone being capable of functioning independently of =any.:other rzone of lower vacuumL within the apparatus While -servingfto exhaust Ya :given runit of plant. y i

3. The Vability of anyone or more-vacuum generating zones to continue functioningy efficiently despite the. free' admission ,-of air to la zone-of lower vacuum. y v l 4 4. Thefemp'loyment of oneor more 'high vee locity liquid `jets/common to all vacuum generating zones Within the apparatus.y

" v5. The recurring use of the same jet liquid during-'its `once-'through traverse` of vthe separate zones oftheapparatus; "'16: Ease vof 'construction 'in when required forhigh capacity jduty. Y

"-7. 'The combined ,attributesofv extremesimplicit'y, compactness, j low rst cost, low cost of operation, absencaofmoving and wearing parts,

i extreme economy .of operating liquid,flexibility,

adaptability, together With the synchronous operation fof fthe independentzones of thefapparatus in performing their duties.

An vobject 'of my inventionzaccordingly. consists inthe provision of` a new Aform of condenser. ca-

;pable lof generating simultaneouslyiseveral .dif-

ferentdegreesof vacuum separate-fand. independent `of each other, kwhich con'denseriis .characterisedfbyits extremesimplicity, its' high efficiency,

multiple j et `form v compactness, sturdiness, low rst cost, and low cost of operation and maintenance.

Another object is to produce a manifold ejector condenser, either simple or compound, of the type set forth generally in the foregoing, and characterised by its maximum utilisation of Water or other fluid to produce the required condenser action. p

Yet another object is to produce a jet type of ejector condenser employing one or more Water columns as the activating element, in which is maintained the highest practicable ratio of exposed area of the water to its volume, and which provides large capacity with minimum investment.

Accordingly, my invention consists in the various elements and features of construction, and in the operational steps, and in the combination and relation of each of the same With one or more of the others, all as more fully described hereinafter in connection with the accompanying drawings, wherein are depicted, solely by way of illustration and not by way of limitation, several embodiments of my invention which I prefer at present.

Figure 1 shows a partially sectioned elevation of one embodiment of my single jet manifold condenser of compound type suitable for construction in sheet metal.

Figure 2 shows a partially sectioned elevation of an alternative embodiment having modified means for effecting the isolation of the vacuum generating zones, suitable for construction in cast metal.

Figure 3 is a sectional plan view on line A-B of Figure 2.

Figure 4 shows a sectional elevation of a modified form of compound apparatus for high capacity duty, applying multiple jets and multiple assemblies of guide cones.

Figure 5 is a plan view on line C-D of Figure Il.

Figure 6 shows a sectional elevation through one of the standard guide cones I8.

Figure '7 shows a sectional elevation through a zone sealing cone I8c, and

Figure 8 shows a sectional elevation .through one type of final sealing cone |813 with its Venturi discharge tube 26.

In the apparatus the number of guide cones and the length of jet allocated to each vacuum zone or chamber can be varied, within limits, in accordance with the duty required of each zone: i, e., the amount oi gas and/or vapour which must be dealt with in order to maintain the specino degree of vacuum desired.

Owing to the absorption of heat from condensed vapour, the jet temperature is increased during its passage through each zone. In order therefore to ensure an effective temperature difference between the jet and the vapour to be condensed, the first zonewhich receives the coolest water-should be employed for generating the highest vacuum desired, the second zone for the next highest vacuum, and so on.

In any given embodiment of my invention, each vacuum generating zone of the manifold condenser, is contrived to` maintain a given degree of vacuum under a given load. Should the load become less, the degree of vacuum will rise above the desired point. Where desirable to stabilise the vacuum therefore, I employ shifter valve means which compensates for the reduction in load by bleeding air into the generating zone concerned.

In that the component zones or ychambers of the apparatus do not cooperate to produce a given peak vacuum, the apparatus is not multistage in character. A

In that the number of component zones is not limited to two only, the apparatus is not compound, in the sense in which this term is used in the art.

In the manifold condensers as shown in Figures 1, 2 and 4, the ejector features disclosed in our previous U. S. Letters Patent Nos. 1,641,349 and 1,864,809, as described in further detail hereinbefore, are employed, but I have so contrived that different intensities of vacuum are simultaneously obtainable from the one condenser apparatus. Such modification is in the main achieved by isolating within separate chambers, groups of guide cones through which a common iet passes.

Though the drawings illustrate embodiments of compound character having two vacuum generating zones only, other embodiments may be of multi-Zone type having three or even more zones, provided that the pressure of water issuing from the inlet nozzle is sufficient .toV overcome the combined friction of the cone throats, plus the external atmospheric pressure against which the ejector has of course to discharge.

Referring now to Figure l, a vertical positioned casing I of sheet metal incorporating hermetically attached head 2 and a base 3 is provided for housing the condenser elements.

While casing I may be of any suitable shape, it is shownv as having the general form of a truncated cone, tapering from its inlet end to its lower or outlet end. In the embodiment shown I prefer to use this form when constructing from high priced or light gauge material such as stainless steel as it saves metal and imparts greater strength than would be tthe case with a cylindrical form.

The space within the casing I is divided into two vacuum generating zones 4 and-5, the upper zone 4 being that within an annular chamber 6 and the lower zone 5 being that within the casing I but external to the annular chamber 6. The cross sectional area-s of the vacuum generating Zones 4 and 5 should be such as to allow low velocity access of the vapours to th iet.

A jointed cover plate 'I is provided for closing a large opening 8 in the head 2 which cover plate 7 is fastened to the head 2 in any desired convenient manner as by means of studs or nuts. The opening 8 provides access to the interior of the condenser for assembling the elements thereof and for inspection.

Casing I is mounted in any suitable manner as upon hollow cast pedestal 9 bolted or otherwise suitably secured to the base 3. The hollow bore I0 of the pedestal 9 serves to conduct the jet liquid from the casing I to drain pipe connection II provided at the side of the pedestal 9. This pedestal 9 has a hanged foot or base I2 preferably of stout construction to provide an adequate support for the apparatus.

Located in the head 2 of casing I are two vapour inlet ports I3 and I4 of areas adequate for the passage of the incoming vapours and so constructed as to provide convenient connection to the units of plant to be exhausted by the condenser. The vapour inlet port I3 is connected through the head 2 to the annular chamber 6 and provides access for vapour to the upper zone 4 of the condenser. The other inlet port I4 provides access for vapour to the lower zone 5 of the condenser. Obviously port I4 could be located-anywhere on the conicaly casing I, but itis usually desirable for both ports I3 and I4 to be on the same plane, although not necessarily vopposite .each other as shown. An annular `recess I5 is provided in the top interior circumference of the head 2 whichderecess I5.

The active elements .ofthe condenser take the form rof a set'ofinverted nested cones I8, disposed in spaced relation `to each other and aligned on their vertical axis longitudinal of the condenser. Each of the cones I8 is `formed'with a circular fiange I9 at the base thereof and a parallel throat orifice atl the apex (see Figure 6). To provide for the progressive expansion of -the jet liquid-approximately 22% per` foot in the case of the embodimentv being consideredthe areas of the v`cone orices increase in harmony with the jet from that of the rst coneISa to thatv of the last conel Ib. An inlet nozzle 2| is threaded or otherwise secured in a boss 22 disposed centrally on the cover plate 1 in alignment with the said cone assembly. I

.The function of theannular chamber 6 is 'to enclose the zone 4 isolated from the remaining zone l5 within the casing I. The two zones 4 and 5.thus in eiect serve as separate vacuum generating regions'oi the same condenser, employing in common the same jet of water or other liquid indefromnozzle 2| but otherwise functioningl pendently of one another.

Located withinfeach'zonel and 5 is a group of the conesl'8, the number apportioned to each zone being roughly proportional to the duty required of eachv zone v`as previously explained in the preamble hereto; f

Y To :the base of the vannular 'chamber 6 is atltachedv an internal flanged ring 23, the sheetl ymetalwall ofthe chamberv 6 being curvedinward of accessibility `the extension screws 25' pass .up s

through 'holes inthe flange I9b of first cone Isa and terminate in squared vends 25a.

- lThe rst or top cone 'Ia of the assembly'has its flange II-lb of such vdiameter as to provide a neatfsliding fit inside the chamber-flange I6. This arrangement `serves to centralise the alignment of the cone assembly in harmony with the nozzle'ZI. The flange Illb of cone Ia has ports "I'Bd through. it to allow the passage of vapour,

similar to those shown in 'Figure 3.

'I'he sealing cone I`8c has athrcat orifice 20 (Fig. '7) which is longer than those of the other cones. Its orice 20 is the only'means of communication between the zones 4 and 5 and in operation issealed by. the jet.

The last or bottomconeflb of the assembly has vattached to its throat a Venturi dischargey assembled they canlsu'pport the nest lof cones.4 -75 amener .all

For structural"fconvenience prefer :to formlzthjis cone .IBb and nozzle v2li in'ztwo parts .superimposed in vthreaded engagement and having flanged contacting vfaces 2.8. 'The bottom end ofthewebbed Venturidischarge nozzle 26 is flanged fat-23 and jointed to the base .3, and has la threaded extension 130 whereby the flangey29 is drawn tighten to its jointing by means of 'nut 3l.

Into the upper flange I 9c of cone. I8b are screwed preferably three shouldered locating rods 32 set equidistant to each other `r and concentric to the axis Iof the `cene assembly. These rods 32 pass with minimum clearance through similarly located holes inthe flanges lof the other cones, which are spaced at desired intervals and in true horizontal planes by means of" distance sleeves 33 mounted on the rods 32, The rods 32 just project through the flangef'I'Sb yof .the viirst cone I8a `and terminate iny Athreaded portions whereon nuts 34 serve to hold the complete vcone assembly `firmly clamped in aligned position.

,Mounted in convenient pcsition'onr casing Iis shifter valve means .35 connected Ato the lower vacuum zone 5 and consisting of 1an internally seated Lvalve 35a connected axially by va Bowden wire to end of fulcrum lever 35h carrying .a suitable weight 35e in adjustable location. Ports 35d invalve housing 35e admit'atmospheric pressure to the valve 35a. By suitably locating the position of the'weight con'the fulcrum lever 35h, the vacuum lwithin the' #zone 5 may' be checked from exceeding the degreedesired, by .the automatic admission of air dueto'a state rof ecpdilibriumk beingA reached between' the mechani- .cal leverage of ythe weight 35o and the Aatmospheric pressure upon the valve 35a. y

In the alternativev embodiment shown in Figure 2 there are also two separate vacuum generating zones 4 and 5 with their respective vapour inletpipes or ports I3 and I4 butfor Ireasons of accessibility and simplicity `of lconstruction .in cast metal the vupper portion 35 of the condenser is made detachable "from the lower portion 31 by constructing the casing I in vtwo sections, jointed in approved fashion as by flanged joint 38. The upper portion k353 contains thezone 4 and part of'zone 5 while the lower portion 3l contains the remainder of zone 5 terminating yat bulkhead '39, and also serves to receive the discharged -jet for delivery to waste viav drain connection II vas well -as serving to support the condenser `and any units of plant whichfmay bemounted thereupon. f

The upper vacuum generatingzone/l which embraces vapour inlet port lI3 'is isolated Afrom the lower zone 5 partly by means of a division or bulkhead vdll-which projects from the wall of the upper condenser portion l36. This bulkhead 4l)A has a large .port 4I therein for the passage of vapour. Bordering the' port 5| land extending upwards. to embrace the vapour inlet port i4 is a partition 42 lwhich is attached by soldering or suitably secured round its margin. The partij tion 42 completes the isolation of zone 4 and together with the wall of the upper condenser portion 36 serves to provide a'passage-way to the lower zone 5 for vapour entering via port I4'.

As .in the case of Figure 1 vthe port e' i 4 could be .located anywhere on. the lcasing .of yzone 5 but is shown on the sameplane as port I3 for the reason mentionedy when discussing'Figure 1. Similar methods for aligning, mounting and spacing vtheconeassembly are employed as in the case of Figure 1. As constructedin Figure 2, however,A each zone has vindependent 'locating rods 32 and 32a'which are screwed into bulkheads 40 and 39. The :first cones Ia and I8d in each zone 4 and 5 are of flanged type similar to cone Ia, in Figure l for providing alignment and also have ports 19d (Figure 3) for the passage of vapour. The first cone I8a and the cone Id are suspended by their flanges ISa and lSb the which are jointed to the respective bulkheads 39 and 4B and held firm thereon by locating rods 32 and 32a and nuts 34 and 34a. Not being required to provide any support for the cone assembly, the cone Ib and Venturi discharge outlet 26 are in this case not webbed.

In the multiple jet embodiment shown in Figure 4 there are again two separate vacuiun generating zones 4 and 5 with their respective vapour inlet ports I3 and I4 (Figure 5) the which could of course be located anywhere that would serve tc independently admit the vapours to the respective zones 4 and 5.

As in the case of the condenser shown in Figure 2 the multiple jet condenser is constructed in two portions 35 and 31 and the vacuum generating zones 4 and 5 are isolated in a similar manner, a partition 42 (Figure 5) being again employed.

In the embodiment shown there are three nozzles 2I which enables liquid to be introduced under pressure to an equal number of separate cone assemblies aligned thereto, said cone assemblies being in all respects constituted as in the case of Figure 2 with the exception that the first cones I8a and the cones |801 are in each case mounted in common alignment plates 43 and 44 respectively having vapour ports 45 therein (see Figure To ensure the supply of water at a temperature and pressure common to the several cone' assemblies an inlet water manifold 46 encloses the several nozzles 2 I, the common pressure water supply entering at 41.

It will be obvious that all general conditions such as temperature and pressure of ejector water, nozzle sizes, vacuum levels and such like, being common in each case, the capacity of the multiple condenser Figures 4 and 5 will be threefoldthat of either of the condensers shown in Figure 1 or 2.

The multiple manifold condenser can be constructed with any number of nozzles and corresponding cone assemblies to suit the magnitude of the load it is required to carry.

All parts of the apparatus hereinbefore described are constructed of metal.

In operation. (Figures 1 and 2) water or other suitable liquid is injected under adequate pressure through inlet nozzle 2I. This liquid hereinafter referred to for convenience as water, passes downwardly at high velocity through the aligned oriflces 20 of the cone assembly and issues from the Venturi nozzle 26, from whence the water discharges through pedestal pipe 9 and drain pipe connection II. The jet of water passes en route through both vacuum generating zones 4 and 5.

In passing through the zone orices 20 the water jet is subject to a grazing and expanding action which ensures the maximum exposure of its component particles and which coupled with its high velocity alects the condensation of vapour and/or ejection of gas.

By connecting the 'ports I3 and I4 to the units of plant to be exhausted, vacuums are produced I3 and I4 is by way of the orifice 20 of sealing cone Hic. Since this orifice is continuously sealed by the jet, the vacuum generated during its passage through the top zone 4 is wholly independent of and unalected by that generated in zone 5.

It is to be remembered that the seal between the two zones i3 and i4 is obtained by the jet passing through the two elongated parallel sides of the throat of the cone idc. To obtain an elective seal under ordinary conditions it is usually necessary for the said throat to lbe twice as long as the ordinary ejector cone throat I8. It will be obvious, however, that the length of the throat of the sealing cone will depend on a number of factors amongst which are (a.) the velocity of the jet, (b) the load to be disposed of, i. e. vapours and/or gases, and (c) the diierence in vacuum between the zones I3 and I4. Where the apparatus is intended to `function so that the zone I3 is still under Vacuum when that in zone I4 is broken then the throat of the sealing cone 80 must be sufficiently elongated to take care ci the difference between the degree of vacuum obtainable in zone I3 and atmospheric pressure in zone I4.

The temperature of the water jet being at its lowest as it issues from nozzle 2l, the top zone 4 is employed for exhausting the unit of plant in which the highest level of vacuum is desired. The water which issues from sealing cone 80, though warmed by the heat absorbed in zone 4, is capable of generating a vacuum in the system connected with zone t, though notlof the same degree as is produced in that connected with zone 4. However, the vacuum generated in the second zone 5 is usually in excess of the degree required, hence in such case I employ snifter valve means 35 to curtail the vacuumto the desired degree. Such shifter valve means 35 may also be employed with the first zone 4, if required to suit the purposes of the operator.

By the use of insulated jacket Il (Figure l) on the wall o annular chamber 6 which encloses zone 4, a somewhat better performance maybe obtained from the said zone 4 owing to the reduced transfer of heat thereinto from the higher temperature vapour within zone 5.

The apparatus may be readily dismantled for inspection as for instance (Figurel) by removing the cover plate '1, unscrewing the extended screws 25 and the nut 3i, the complete cone assembly can be withdrawn.

The multiple condenser shown in Figure 4. operates in precisely the same manner as do the single jet condensers shown in Figures l and 2 except that the load is shared in this case by three ejector assemblies operating in parallel.

Having now explained lthe nature of the objects of the invention and having specically described constructions embcdying the invention, what I claim is:

l. Adevice of the type described, for simultaneously producing a plurality of separate degrees of vacuum comprising a set of spaced, axiallyaligned cones, iianged at their broader ends, support rods extending through the flanges of said cones to maintain them in 'aligned and spaced` `relation to provide tapered openings of proper dimensions between adjacent cones, means for setting off said cones in a plurality of separate chambers 'disposed one atop the other, and connected with each other solely by the passage provided through said cones, an inlet in the topmost chamber for introducing an activatlng iiud into the passage through said cones,

. aligned with .said set of cones,

Y said opening,

each. ci,`4 said chambersvv having an opening for connectingithem 'to apparatus to be subjected to having-sthermally-insulated side walls, hung infteriorlyrfrom the region of the. top ofv said cas,- ing; and separatingI said casing, into chambers', and: encompassing a predetermined numberv of said cones, sothat each of said chambers vcontainsealselected numberv of cones, and means-for separately connecting each of said chambersto apparatus tdbesubjected to thegenerated vacllilmz.

3f. A device. of 1 the type` described, for simultaneously producing a plurality of separate de,- grees ofvacuum, comprising an elongatedcasingr, having an inlet near vone end thereof, a set of spaced, axially-aligned cones in said casing thezpassagesof whichcones are in communication; with ,saidxinlet opening in the casing, means number rof cones to define separate chambers,

, said casing having openingsleading oneto each of A,said .cham-bersfor connecting the chambers to apparatus to be. evacuated, a discharge nozzle disposed atthe discharge lend of said casing and and apedestal pipe on which said casingA is mo-unted on end, and into. which said discharge nozzle opens, said pedestal pipe having an opening to drain.

4., A deviceof the type described, for simultaneouslyv producingl atpluralityV of separate 4degrees ofvacuum `comprising a casing having an inlet opening at one `endy thereof, a ycover plate` over an inlet iiuidnozzle in said cover plate, a cylindrical` partition slung interiorly of saidrcasing near the top thereof,-in spaced relationy withl said casing, `a set of spaced, axiallyalignedv cones disposed vertically of: said casingv and having centralrpassa'ges' aligned withsaid inlet nozzle, said partition separating said casing.. into chambers, and itself encompassingA a predetermined number of saidy cones, so that each of saidchambers contains a selected numberlof cones, and means `for separately connectingeach-k ofi said chambersv to apparatusito be subjected to the generated vacuum'.y

"51A device of the type described, -for simultaneously producing a plurality of separate de-l grees of vacuum, comprising a casing, a plurality off sets off spaced, axially-aligned cones disposed y vertically ofsaid casing, the cones of each set having a central passage therethrough, aligned with'aV corresponding. .inlet opening in said casing,'means for passing a fluid stream through the passages of each set of cones, a partition in said 'casing separating the latter into chambers, and encompassing a predetermined number of cones of each set of cones, so that each of said chambers contains a selected number of cones in each.

set thereof, and means for separately connecting each of said chambers to apparatus to be subjected to the generated vacuum.

6. A device of the type described, for simultaneously producing a-plurality of kseparate degrees of; vacuum, comprising a casing, a plurality of. setsiofgspaced, aXially-alignedcones disposed vertically of said casing, the cones of each setl havingcentralpassages therethrough, a distributorheadat; the` inlet end of saidv casing, for distributing-condenserv fluid to each said set of cones,l thepassages of each set ofcones being alignedawith the uid opening which, supplies the same, a partition in said casingy separating theI lattery into chambers, and encompassing a setting off said cones ingroups of predetermined predetermined number of cones to` each setk of cones, so., that each'off said` chambers contains a" selected numberofr cones in each set thereof, andmeansxforseparately connecting each of said chambers to apparatus to be subjected to the generated; vacuum;

7'. An., ejector-condenser fory vapors andy gases, comprising', in combination\,; a casing; a partition dividing said casingl into a pair of lvacuum-gen,- eratingf-vaporacondensing; chambers, a suction inletioreachsaid chamberzmeans for introducing-a'vjetoi; liquidinto onev of said chambers, a seriesof apertured axially-,aligned guide elements disposed in; each chambe ftheLseveral series of guide-elements ,likewise beingaxially alignedv with respectto each other, whereby a jet` of` liquid from said iirst-mentionedmeans can ow through the aligned apertures ofr said elementssaid elementsrbeing spaced from each otherA to `expose the liquid flowing therethrough to the atmosphere of.v saidg-casingrandlto permit contact of said atmosphereciY theA casing with the rliquid passing therethrough to effect; the condensation of condelflsilolle.A vapors; therein Aand at the same time produca cent guide, elements; the degree.y of vacuumbeing4 determined by theinitial and terminal velocities and temperatures of the liquid and con,- densible-Vapors and gases;V which are passed througli;- said elementstogether with lthe number ofA guidaelements inr each; series,l it being possible-tofy obtain widely different degrees of vacuum', in the several; chambers.

8;y An ejector-condenser forvapors and gases, comprisingin combination, a casing, a partition dividingisaid casinginto aV pair of'vacuum-generating'vapor-condensing chambers, a suction inlet foreach said chambermeans for introducing a jet of liduidintoonefof said chambers, a series of aperturediaxiall'y-aligned guideV elements disposed in each chamber, the several seriesof. guide elements likewise being axially aligned with `respect vto, each other, each` said element having an extending, flanged portion adjacent toandv directedtowards theinlet end of the condenser, merging into a constricted portion adjacent wards they outlet end vof the condenser, whereby a jetof liquid; from-` said first-mentioned means can flowl through the alignedyapertures of. said elements, said elements beingA spacedfrompeach other to. expose they liquid flowingV therethrough to thev atmosphere of said; casing and to permit contact of. said atmosphere of the,y casingy withv thee liquidI `passing ,therethrough ,tov effect Athe condensation of condensible vapors therein and at the same time produce a vacuum in the spaces vbetween adjacent guide elements, the degree of 'vacuum being determined by the initial and terminal velocities and temperatures of the liquid and lcondensible vapors and gases which are passed through said elements'together with the number of guide elements in each series, it being possible to obtain widely different degrees of vacuum in the several chambers.

a-Vacuum in thev spaces between` adja-v to and directedy tol from said first-mentioned means can flow through the aligned apertures of said elements, said elements being spaced from each other to eX- pose the liquid owing therethrough to the atmosphere of said casing and to permit contact of said atmosphere of the casing with the liquid passing therethrough to effect the condensation of condensible vapors therein and at the same time produce a vacuum in the spaces between adjacent guide elements, one said guide element serving as a seal between the pair of chambers and being of length suflicient to provide a liquid seal therebetween capable of sealing those chambers against each other, the degree of vacuum being determined by the initial and terminal velocities and' temperatures of the liquid andv condensible vapors and gases which are passed through said elements together with the number of guide elements in each series, it being possible to obtain widely diierent degrees of vacuum in the chambers.

10. An ejector-condenser for vapors and gases, comprising, in combination, a casing, a partition dividing said casing into a pair of vacuum-generating vapor-condensing chambers, a suction inlet for each said chamber means for introducing a jet of liquid into one of said chambers, a series of apertured axially-aligned guide elements disposed in each chamber, the several series of guide elements likewise being axially aligned with respect to each other, whereby a jet of liquid from said first-mentioned means can iloW through the aligned apertures'of said elements, said elements being spaced from each other to expose the liquid iiowing therethrough to the atmosphere of said casing and to permit contact of said atmosphere of the casing with the liquid passing therethrough to effect the condensation of condensible vapors therein and at the same produce a vacuum in the spaces between adjacent guide elements, and a Venturi column disposed coaxially at the end of the last series of guide elements to increase the eiective velocity of the jet of liquid, the degree of vacuum being determined by the initial and terminal Velocities and temperatures of the liquid and conn densible vapors and gases which are passed through said elements together with the number of guide elements in each series, it being possible to obtain widely different degrees of vacuum in the several chambers.

11. An ejector-condenser for vapors and gases comprising in combination, a casing; a partition dividing said casing into a pair of serially-connected, vacuum-generating, vapor-condensing chambers; a suction inlet for each said chamber means for introducing a jet of liquid longitudinally into one of said chambers; a series of axially-bored aligned guide elements disposed in each chamber, the guide elements of each series being coaxial with respect to each other and the several series being coaxial with respect to each other and to said first-mentioned means so that the liquid is common to said elements and passes through the bore thereof, the elements being spaced from each 'other a distance such that the ratio of exposed area of liquid to the volume thereof is a maximum and to permit maximum area of contact of the atmosphere of a particular chamber with the liquid passing therethrough While at the same time ensuring that a vacuum is created in the spaces between adjacent elements, the maximum degree of vacuum obtainable being determined by the initial and terminal velocities and temperatures of the liquid, and the number of guide elements in each series being sufficient to exhaust the maximum unit volume of fluid from the corresponding chamber; and means provided in desired chambers, acting independently of the other chambers, for admitting external air, upon and as an incident to increase in the vacuum Within the chamber beyond a desired value, to restore the vacuum to the desired maximum value.

12. An ejector-condenser for vapors and gases, comprising, in combination, a casing; a partitition dividing said casing into a pair of serial ly-connected vacuum-generating vapor-condensing chambers; a suction inlet for each said cham ber means for introducing a jet of liquid longitudinally into one of said chambers; a series of axially-bored aligned guide elements axial with respectl to each other and the several series being coaxial with respect to each other and to said iirst-mentioned means so that the liquid common to said elements and passes through the bore thereof, the elements being spaced from each 'other a distance such that the ratio of exposed area of liquid to the volume thereof is a maxiv mum, and to permit maximum area of Contact of the atmosphere of a particular chamber with the liquid passing therethrough while at the same time ensuring that va vacuum is created in the spaces between adjacent elements, the cross-seetional area of the bores of the guide elements in each series, and of the successive series of elements, progressively increasing from inlet tc outlet, to accommodate the increased cross-sectional area of the jetof liquid as the latter passes through the condenser, the maximum degree of vacuum obtainable being limited by the maximum of the terminal velocities and temperatures o1 the liquid, and the number of guide elements in each series and the length of path of liquid through the guide elements of that series being sufficient to exhaust the maximum unit volume of fluid which may be expected from the corresponding chamber.

HENRY LAMONT MURRAY. 

